生物质燃料进料比在共燃循环流化床锅炉中的影响:计算流体动力学研究

Sorathan Tanprasert, Nuttima Rangton, Warunee Nukkhong, Pitakchon Wises, P. Piumsomboon, B. Chalermsinsuwan
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引用次数: 0

摘要

如今,全球人口显著增加,能源消耗也逐年激增。对化石燃料的普遍依赖,尤其是在发电方面,严重加剧了环境污染和全球变暖。循环流化床因其在燃烧室中的连续运行和有效传热而成为一种突出的锅炉类型。此外,生物质燃料具有可再生和环保的特点,使用生物质燃料是一种有吸引力的选择。因此,探索将煤炭和生物质作为锅炉燃料进料的联合燃烧系统前景广阔,需要对其进行优化,以实现高效的能源生产和减少气体排放。本研究采用计算流体动力学模拟锅炉内固体燃料和烟气反应的复杂相互作用,利用双流体法进行多相流模拟。重点研究的循环流化床锅炉采用次烟煤、木屑作为生物质源,沙子作为床层材料。根据运行数据(包括床层温度、烟气出口速度和二氧化碳质量分数)进行的模型验证表明,偏差极小。在研究生物质比率对燃料进料的影响时发现,随着生物质比率的增加,二氧化硫排放量会减少,这是因为与煤炭相比,木屑中的硫含量较低。然而,由于混合固体燃料的热值发生变化,木屑混合比的提高会降低锅炉效率。优化后的生物质与煤的给料比确定为 59.15%,锅炉效率达到最大值 82.84%,硫氧化物和氮氧化物的污染气体排放量降到最低,符合工业标准。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Impact of Biomass Fuel Feeding Ratio in Co-firing Circulating Fluidized Bed Boiler: A Computational Fluid Dynamics Study
Nowadays, our global population is on a notable rise, coupled with an annual surge in energy consumption. The prevailing reliance on fossil fuels, especially in electricity generation, has significantly contributed to environmental pollution and exacerbated global warming. The circulating fluidized bed, distinguished for its continuous operation and effective heat transfer in the combustion chamber, emerges as a prominent boiler type. Furthermore, the use of biomass fuel, recognized for its renewable and environmentally friendly characteristics, presents an attractive option. Hence, exploring a co-firing system incorporating both coal and biomass as fuel feeds for the boiler holds promise, necessitating optimization for efficient energy production and reduced gas emissions. This study employs computational fluid dynamics to simulate the intricate interactions of solid fuel and flue gas reactions within the boiler, utilizing the two-fluid method for multiphase flow simulation. The circulating fluidized bed boiler in focus employs subbituminous coal, woodchips as biomass sources, and sand as the bed material. Model validation against operational data, including bed temperature, flue gas velocity outlet, and carbon dioxide mass fraction, indicates minimal deviation. Examination of the biomass ratio's impact on fuel feed reveals a reduction in sulfur dioxide emissions with an increasing biomass ratio, attributed to the lower sulfur content in woodchips compared to coal. However, a heightened woodchip blending ratio results in diminished boiler efficiency due to the altered heating value of the mixed solid fuel. The optimized biomass-to-coal ratio in fuel feeding is determined as 59.15%, achieving a maximized boiler efficiency of 82.84% and minimized pollution gas emissions of sulfur oxide and nitrogen oxide in accordance with industrial standards.
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